alkene reactions - American Chemical Society

Mar 3, 1983 - Iron/Alkene Reactions: A Matrix Isolation Infrared and Móssbauer Investigation1. STEWART F. PARKER,* * CHARLES H. F. PEDEN,* PAUL H...
0 downloads 0 Views 734KB Size
Znorg. Chem. 1983, 22, 2813-2818

2813

Contribution from the Departments of Chemistry and Physics, University of California at Santa Barbara, Santa Barbara, California 93106

Iron/Alkene Reactions: A Matrix Isolation Infrared and Mossbauer Investigation' STEWART F. PARKER,+ CHARLES H. F. PEDEN? PAUL H. BARRETT,* and RALPH G. PEARSON*+ Received October 1S, 1982

The reactions of matrix-isolated iron atoms and clusters with the alkenes ethylene and propylene have been investigated by infrared and Mbsbauer spectroscopies. In ethylene at low temperatures ( 2). The Mbsbauer spectra of the products indicate that the electronicconfiguration of the iron atoms in the alkene complexes is approximately (4~)'(3d)~, in agreement with theoretical work. The Mbsbauer spectra of Fe(C2H4)and Fe(C3H6) are also consistent with the proposal that C2H4 and C3Hs are primarily u donors with only minimal d,-*r* back-bonding.

Introduction The mechanistic details of the reactions that occur on single-crystal surfaces and on heterogeneous catalysts are not well understood. It has been proposed2 that well-defined metal clusters or even single atoms are reasonable, simple models of the more complex larger systems. This view has been ~hallenged.~ Matrix isolation is one technique whereby a single atom or a few atom cluster is allowed to interact with a reactant under controlled conditions, usually without the complication of additional ligands. In spite of its widespread use in industry as a heterogeneous catalyst, there have been relatively few matrix isolation studies of iron and its reactions. In addition, S7Fe(2.2% natural abundance) shows the Mossbauer effect. This Mossbauer isotope has narrow lines and hence good resolution. It is also one of the most straightforward to use experimentally. The Mbsbauer effect allows the direct observation of each type of iron atom present. The resulting spectrum provides information about the electronic environment, the local symmetry, and the stoichiometry of the iron complex. Infrared spectroscopy provides complementary information about the coordinated ligands. Thus together the two forms of spectroscopy give a more complete picture of the iron complex. We have chosen to investigate the reactions of iron atoms and clusters with simple alkenes in order to provide a model for the reactions of alkenes at an iron surface. Experimental Section Detailed descriptions of both the Mbssbauer' and the infrareds vacuum systems have been published. In brief, the samples for infrared spectroscopy were prepared by deposition onto a NaCl window held at 16-20 K by an Air Products Displex closed-cycle refrigerator. Iron was evaporated either from resistively heated iron powder (Research Organic/Inorganic Corp. 99.99%) in an alumina crucible held in a tantalum furnace or by direct resistive heating of an iron foil (Materials Research Corp. 99.99%) clamped between water-cooled electrodes. Foil evaporation was more difficult to control but resulted in lower temperatures at the cold window. Temperatures were measured with an optical pyrometer and were typically 1450-1550 "C for the crucible and 1250-1350 OC for the foil. Infrared spectra were recorded on a Perkin-Elmer 683 spectrometer. This was interfaced to a Radio Shack Model I1 TRS-80 microcomputer. Samples for Mossbauer spectroscopy were prepared on a Be disk at 4 K with a Janis liquid-helium cryostat or an Air Products Mijssbauer Displex closed-cycle helium refrigerator. This uses a helium exchange gas, resulting in higher temperatures during deposition than the Displex used for the infrared experiments. All the Mossbauer Department of Chemistry. 'Department of Physics.

experimentsused s7Fe(New England Nuclear 95.85% enriched). This was evaporated from an alumina crucible held in a furnace similar to that used for the infrared experiments. Mossbauer spectra were recorded with a conventionalconstant-acceleration spectrometer using a 57C0/Rhsource. A natural-abundance a-Fe foil at room temperature was used for calibration. All isomer shifts are given with respect to a-Fe. The multichannel analyzer output was also interfaced to the TRS-80. The Mossbauer spectra were computer fit to a sum of quadrupole doublets with either the TRS-80 or a VAX/PDPl 1. The pairs of peaks were constrained to have equal amplitudes and full widths at half-maximum. A Lorentzian line shape was used to each peak. The standard statistical tests X2 and MISFITwere used as quantitative measures of the quality of the fit. Argon (Linde 99.999%),ethylene (Linde 99.5%), ethylene-1,2-l3C2 (Merck Sharp and Dohme 90 atom % I3C), and propylene (Linde 99.5%) were used without further purification. RMults Infrared Experiments. When Ar/C2H4 gas mixtures are condensed with iron vapor at 16-20 K, new infrared absorptions appear in the regions 1550-1450 and 1250-1150 cm-'. These bands only appear when iron and ethylene are present in the matrix. Background experiments without iron, but under otherwise identical conditions, do not show these bands. When iron is present, the new bands, although weak, occur and are consistently reproducible. These spectral regions are characteristic of ethylene coordinated to metal atoms and clusters. The vibrations correspond mainly to the C - C stretch and C-H bend of the coordinated olefin, although normalcoordinate analyses of ethylene complexes6*'show that these vibrations are extensively mixed. At the lowest iron concentrations two new absorptions appear at 1491 and 1215 cm-'. (The latter band partly overlaps a weak band due to unreacted ethylene at 1220 cm-I.) These bands appear with a constant intensity ratio in matrices containing from 1 to 100% C2H4(Figure 1) and during warm-up experiments. The Occurrence of these bands at the lowest iron and ethylene concentrations suggests that the species consists of only one iron atom and one coordinated ethylene. In addition, its presence in pure ethylene implies that this product is the only monoiron complex formed. The stoichiometry of the complex is confirmed by the concentration dependence of the 1491-cm-' band and by (1) A preliminary report of this work was presented at the 3rd International Matrix Isolation Conference, Nottingham, England, July ZOth, 1981. (2) Muetterties, E. L.; Rhodin, T. N.; Band, E.; Brucker, C. F.; Pretzer, W. R. Chem. Rev. 1979, 79, 91. (3) Moskovits, M. Acc. Chem. Res. 1979, 12, 229. (4) McNab, T. K.;Barrett, P. H. 'Mkbauer Effect Methodology"; Plenum Press: New York, 1971; Vol. 7, p 59. (5) Peden, C. H. F.; Parker, S . F.; Barrett, P. H.; Pearson, R. G. J. Phys. Chem. 1983,87, 2329. ( 6 ) Nakamoto, K. "Infrared and Raman Spectra of Inorganic and Cwrdination Compounds", 3rd ed.;Wiley: New York, 1978, p 383. (7) Andrews, D. C.; Davidson, G. J . Organomel. Chem. 1972, 35, 161.

0020-1669183I1 322-28 13%01.50/0 , 0 1983 American Chemical Society I

,

2814 Inorganic Chemistry, Vol. 22, No. 20, 1983

Parker et al.

I

cm-I

1500

Figure 1. Infrared spectra, showing the absorptions of Fe(C,H,) (A),

and 8C--H regions at 15 of ethylene-containing matrices in the -v K (a) Ar/CzH4(10%);(b) Ar/C2H4(1.5%)/Fe(0.4%); (c) CzH4/Fe (0.5%).

mixed-isotope ("C2H4/ 13C2H4)studies. The intensity of the 1491-cm-' peak is proportional to the first power of the iron concentration. This is good evidence that the absorbing species contains only one iron atom. The mixed-isotope studies (Figure 2), particularly in the 1500-1450-cm-' region, show that the species contains only one coordinated C2H4 molecule. The absence of any new absorptions between the 1491/ 1469-cm-' doublet of Fe( 12C2H4)/Fe(13C2H4)respectively is good evidence for a single ethylene coordinated to an iron atom. If the complex were Fe(C2H4), (n > l ) , then in addition to the peaks corresponding to Fe( 12C2H4),and Fe( 13C2H4),,there would have been the absorptions of the mixed 12C2H4/13C2H4 complexes Fe(13C2H4)i(1tC2H4),i (1 Ii In - 1). When the matrices with low concentrations of iron are warmed to 35 K and recooled for spectral recording, two new absorptions at 1510 and 1246 cm-' grow in together. There is a simultaneous loss in intensity of the peaks of Fe(C2H4) (Figure 3). The mixed-isotope studies show only a doublet for this new species in the C-H bend region. This is inconsistent with a reaction of the type

-

Fe(C2H4) + C2H4 Fe(C2H4)2 (1) because such a product would be expected to show a triplet of absorptions in the mixed-isotope studies as has been observed for C U ( C ~ H ~ Furthermore, )~* for all the metal/olefin systems that have been examined in pure ethylene, on deposition, the major mononuclear product, M(C2H4),, is the one that has the largest possible value of n for the given metal M; e.g., n = 3 for Ni, Pd. This would imply that the species responsible for the 151O/ 1246-cm-l bands should be the major product before annealing, which it is not. The reaction Fe(C2H4) + Fe(C2H4)

-

C2H4-Fe-Fe-C2H4

(2)

in consistent with the evidence. If the vibrational coupling between the two ethylene molecules across the Fe-Fe bond were small, then the isotopic spectra would only show a doublet (8) Ozin, G. A.; Huber, H.; McIntosh, D. Inorg. Chem. 1977, 16, 3070.

I

I

I30y c rn-

I100

Figure 2. Infrared spectra of (a) Ar/l2C2H4(10%)/Fe (1.5%)(XS expansion), (b) Ar/l2CZH, (10%)/'3C2H4(10%)/Fe (1.2%) ( X 5 expansion), (c) Ar/13C2H4(10%)/Fe (1.2%),and (d) X5 scale expansion of (c) showing the isotope patterns of the iron/ethylene reaction products. Note that (b) is a superposition of (a) and (c).

2

0 cn c"

5z a

[L

I-

I500

I300

110

cm-I

Figure 3. Infrared spectra of Ar/CzH4(10%)/Fe (0.7%) (a) as it is deposited at 17 K and (b) after it is annealed to 35 K and recooled to 17 K, showing the reaction A B.

-

and not a triplet. Minimal vibrational interaction across a metal-metal bond has been observed in a number of systems for both ethylene (M2(C2H4)2,M = C O , Cu8) ~ and carbon monoxide (M2(C0)2,M = Ni,l0 Cull). By analogy to Ni2(C2H4)x (x = 1,2),12the breadth of the bands (-15 cm-') and their position at higher energy than those of Fe(C2H4) also suggest that they are due to a low-nuclearity cluster. Cocondensation at either a higher temperature, 20 K, or higher iron concentrations results in additional bands (Figure (9) Hanlan, A. J.; Ozin, G. A,; Power, W. J. Inorg. Chem. 1978, 17, 3648. (10) Moskovits, M.; Hulse, J. E. Surf. Sci. 1976, 57, 125. ( 1 1 ) Moskovits, M.; Hulse, J. E. J . Phys. Chem. 1977, 81, 2004. (12) Ozin, G.A,; Power, W. J.; Upton, T. H.; Goddard, W. A,, 111. J. Am. Chem. SOC.1978, 100, 4750.

Inorganic Chemistry, Vol. 22, No. 20,'1983 2815

Iron/ Alkene Reactions

Table I. lnfrared Frequencies" and Assignments for the Iron/Ethylene System species UC=C A A'

C-H

assignt

1491 1469 1510 1485

1215 Fe(12C,H,) 1192 Fe(13C,H,) B 1246 Fez('2C2H4)2 B' 1216 Fe,('3C,H,), C 1186 Fe,('zC,H,) D 1493 br 1220,1200,1172 Fep(lzC,H,)p (p > 2) D' 1465 br 1194,1170,1144 Fep(13CzH,)p (p > 2) " All frequencies (rl) are in cm-' for the products in an Ar/XC,H, (10%) (x = 12 or 13)matrix at 18 K.

cm-l

Figure 4. Infrared spectra of an Ar/C2H4(10%)/Fe (1.5%) matrix (a) as it is deposited at 17 K, (b) after it is annealed to 30 K, and (c) after it is annealed to 35 K, showing the reactions C B and A B.

-

-

4) at 1493 br, 1220, 1200, 1186, and 1172 cm-'. Warm-up experiments indicate that the 1493 br/1220/1200/1172-cm-' bands belong to a single species and that the 1186-cm-' band belongs to a different species. On warming of the matrix to 30 K the 1186-cm-' band rapidly diminishes in intensity and those of Fe2(C2H4)2grow in (Figure 4b). This suggests that the species responsible for the 1182-cm-' band can be facilely converted into Fe2(C2H4)2. Such a species would be Fe2(C2H4). This simply adds C2H4 to give Fe2(C2H4)2: Fe-Fe-C2H4 C2H4 C2H4-Fe-Fe-C2H4 (3) Annealing to 30 K results in little or no change in the intensity of the bands of Fe(C2H4). This is consistent with the difference between reactions 2 and 3. Thus (3) involves reaction with a molecule that is part of the matrix cage, perhaps just a reorientation of the reactants, whereas (2) requires diffusion of the reactants through the matrix, a higher energy process. The identity of the species responsible for the bands at 1493 br/ 1220/ 1200/ 1172 cm-' is less certain. Its production under conditions of high iron concentration, or considerable surface diffusion, all suggest a low-nuclearity cluster, FeP(C2H4)?(p, q > 2). Its persistence up to the point where the matrix is boiling off (40-50 K) supports this assignment. The mixedisotope studies again indicate only a monoethylene product (Figure 2). However, the three C-H bend bands show that there is more than one coordinated ethylene molecule in the complex. Thus for the same reasons as elaborated for Fez(C2H4)2 the isotope data suggest there is one C2H4 per Fe atom. Hence, a reasonable formula would be FeP(C2H4), (p > 2). Table I lists all of the observed infrared bands and their assignments. Mossbauer Results. The Mossbauer spectra (Figure 5 ) of low concentrations (